0.224 litres
2.24 litres
22.4 litres
224 litres
C. 22.4 litres
0.086
1.086
1.086
4.086
Workdone
Entropy
Enthalpy
None of these
Atomisation
Carbonisation
Combustion
None of these
Coal gas
Producer gas
Mond gas
Blast furnace gas
1
1.4
1.67
1.87
Boyle's law
Charles' law
Gay-Lussac law
All of these
Increase key length
Increase key depth
Increase key width
Double all the dimensions
Ru × T
1.5 Ru × T
2 Ru × T
3 Ru × T
Shear force changes sign
Shear force is maximum
Bending moment changes sign
Bending moment is maximum
(σx/2) + (1/2) × √(σx² + 4 τ²xy)
(σx/2) - (1/2) × √(σx² + 4 τ²xy)
(σx/2) + (1/2) × √(σx² - 4 τ²xy)
(1/2) × √(σx² + 4 τ²xy)
Tension in the masonry of the dam and its base
Overturning of the dam
Crushing of masonry at the base of the dam
Any one of the above
Acts at a point on a beam
Spreads non-uniformly over the whole length of a beam
Spreads uniformly over the whole length of a beam
Varies uniformly over the whole length of a beam
Change the shape of the beam
Effect the saving in material
Equalise the strength in tension and compression
Increase the cross-section of the beam
Chain riveted joint
Diamond riveted joint
Crisscross riveted joint
Zigzag riveted joint
mm/mm
kg/cm
Kg
kg/cm²
Two constant volume and two isentropic processes
Two isothermal and two isentropic processes
Two constant pressure and two isentropic processes
One constant volume, one constant pressure and two isentropic processes
Boyle's law
Charles' law
Gay-Lussac law
Avogadro's law
Q1 - 2 = dU + W1 - 2
Q1 - 2 = dU - W1 - 2
Q1 - 2 = dU/W1 - 2
Q1 - 2 = dU × W1 - 2
Brown coal
Peat
Coking bituminous coal
Non-coking bituminous coal
Not deform
Be safest
Stretch
Not stretch
A right angled triangle
An isosceles triangle
An equilateral triangle
A rectangle
Maximum torque it can transmit
Number of cycles it undergoes before failure
Elastic limit up to which it resists torsion, shear and bending stresses
Torque required to produce a twist of one radian per unit length of shaft
pv = mRT
pv = RTm
pvm = C
pv = (RT)m
Dual cycle, Diesel cycle, Otto cycle
Otto cycle, Diesel cycle, Dual cycle
Dual cycle, Otto cycle, Diesel cycle
Diesel cycle, Otto cycle, Dual cycle
(σx + σy)/2 + (1/2) × √[(σx - σy)² + 4 τ²xy]
(σx + σy)/2 - (1/2) × √[(σx - σy)² + 4 τ²xy]
(σx - σy)/2 + (1/2) × √[(σx + σy)² + 4 τ²xy]
(σx - σy)/2 - (1/2) × √[(σx + σy)² + 4 τ²xy]
Constant volume
Constant temperature
Constant pressure
None of these
Increases the internal energy of the gas
Increases the temperature of the gas
Does some external work during expansion
Both (B) and (C)
π /4 × τ × D³
π /16 × τ × D³
π /32 × τ × D³
π /64 × τ × D³
Energy stored in a body when strained within elastic limits
Energy stored in a body when strained up to the breaking of the specimen maximum strain
Energy which can be stored in a body
None of the above
Toughness
Tensile strength
Capability of being cold worked
Hardness